KR20100083050A - A overheat prevnting unit of bus-bar using infrared temperature sesnser - Google Patents

Abstract

PURPOSE: A bus bar overheating prevention device using an infrared ray temperature sensor is provided to install an infrared ray temperature sensor in an entrance to the horizontal direction and to check the temperature of the each bus bars to detect the heat generation in advance. CONSTITUTION: A bus bar overheating prevention device using an infrared ray temperature sensor comprises a bus bar(100) which are installed in the inside of a cabinet(300) and are located on a R,S,T fixed and coupled by a bolt(110), a temperature sensor(200) which is separately installed on a bolt coupling position of the bus bar, an indicator for collecting temperature(400) which wirelessly communicates the collecting the temperature data measured by the infrared temperature sensor, and a controller(500) which alarms if the controller is out of a reference temperature value by being offered the temperature information from the indicator.

Description

A Overheat Prevnting Unit of Bus-bar Using Infrared Temperature Sesnser}

The present invention relates to a bus bar overheating prevention device using an infrared temperature sensor, in particular, the infrared temperature sensor is installed on the inside of the bus bar cabinet, but installed at a point within about 50 cm horizontal to the bolt fastening portion of the bus bar, By measuring the temperature of each bus bar using the infrared sensor and delivering the measured information to the user, it is possible to grasp in advance the fire in the vicinity of the bus bar due to the heat generation due to the abnormality of the fastening part of the bus bar and the fire near the bus bar. The bus bar overheating prevention device using an infrared temperature sensor, characterized in that one.

In general, the power produced in a power plant flows through a bus bar connecting and connecting wires when connected to various measuring devices and branch panels, and a high current of high voltage and high power passes through the bus bar.

In addition, the three-phase large current provided by the power plant is configured to be connected to the bus bar by bolts so that the electrical connection is continuous.

In practice, the busbars are made of wires and square steel and usually pass through a room, such as a cabinet, in which the bolts are joined with secondary busbars so that the electrical supply flows continuously to other devices.

However, when the bolts connecting the primary bus bar and the secondary bus bar are loosened, a contact resistance is often generated to generate heat, and thus, a fire risk is often exposed.

Of course, as a means of overcoming this, by attaching a thermal tape that changes color depending on the temperature of the busbar contacts that are connected by bolts, the operator can check the color of the tape to determine whether heat is generated at the busbar contacts. However, due to the nature of high power, it is inconvenient because it cannot approach the bus bar at any distance, and it is inconvenient because it needs to know whether heat is generated at a long distance. In some cases, you may not be able to determine if fever is occurring.

The reason why heat generation occurs at the bus bar contact portion as described above is that when a large power passes through the bus bar, vibration is generated, and accordingly, the bolt is gradually released to generate a large contact resistance at the bus bar contact portion. This can be easily heard when passing under the transformer to bring down the high power to low power. When the high power passes, it can be easily seen that a vibration sound is generated.

Therefore, since the vibration cannot be fundamentally blocked, if the part connected by the bolt continues to vibrate, the bolt will loosen gradually and a large contact resistance will be generated later. .

However, as described above, there is still a problem that the reliability is inferior by checking the temperature with the naked eye and accurate temperature checking is also difficult.

The present invention is to solve the above problems,

Install the infrared temperature sensor at the door, but install it horizontally at the bolted position of the busbar.In addition, the infrared temperature sensor checks the temperature of each busbar to identify heat in advance and warns if heat above the standard occurs. It aims to block the risk of fire in advance.

As a means for achieving the above object,

The present invention is installed on the inside of the cabinet 300, R, S, T on three bus bars 100, fastened by bolts 110, and installed on the door of the cabinet 300, bolt fastening portion of the bus bar Infrared temperature sensor 200 is spaced in a horizontal direction in a straight line in the horizontal direction, and electrically connected to the infrared temperature sensor 200 to collect the temperature data measured through the infrared temperature sensor to communicate wirelessly The temperature collection indicator 400, and receives the temperature information from the indicator is characterized in that it comprises a control unit 500 for alarming out of the reference temperature value.

In addition, the control unit alarms when the temperature of the bolt coupling portion of the bus bar 100 exceeds 60 degrees, the power delivered through the bus bar when the temperature of the bolt coupling portion of the bus bar 100 exceeds 80 degrees It is characterized by controlling to block.

In addition, the infrared temperature sensor 200 is characterized in that it is installed at a distance of 50cm or less from the bus bar (100).

As described above, in the present invention, the infrared temperature sensor is installed inside the cabinet, but is installed horizontally at the bolt coupling position of the busbar, and the temperature of each busbar is checked to determine the heat due to the overload generated at the bolt tightening position. Therefore, if heat above the standard is generated, it is possible to prevent fire accident by warning fire.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a conceptual diagram of the present invention.

Figure 2 is an installation example of the present invention,

As shown, the components of the present invention are largely installed inside the cabinet 300 and connected to the three bus bars 100 on R, S, and T fastened by bolts 110 and the door of the cabinet 300. Infrared temperature sensor 200 is installed and spaced apart a certain distance horizontally in a linear direction on the bolt fastening portion of the bus bar, and electrically connected to the infrared temperature sensor 200 measured by the infrared temperature sensor It comprises a temperature collection indicator 400 for collecting temperature data and communicating wirelessly, and a control unit 500 for receiving a temperature information from the indicator and alarming when the reference temperature value is out of the reference temperature.

Since the bus bar 100 carries three phases of electric power supplied from a power plant, three bus bars are formed in one pair and are connected through bolts 110.

Each of the three sets of bus bars 100 is formed by combining a first bus bar and a second bus bar, and a joint part is fastened by a bolt 110.

The infrared temperature sensor 200, which is spaced apart in a linear direction from the bolt fastening part, detects the electromagnetic wave shape thermal energy is emitted from the bolt position part, thereby determining how much the temperature of the bolt fastening part is.

In the present invention, the temperature of the three bus bars 100 can be checked using one infrared temperature sensor 200.

To this end, in the present invention, the infrared temperature sensor 200 is installed in the door bar, the bus bar 100 is installed in a straight distance, and the bolt fastening position so that the bolt fastening position and the straight distance of the bus bar 100 Sensing mainly.

The infrared temperature sensor 200 is installed corresponding to the number of bus bars 100, and if three bus bars 100 are present in the room, three infrared temperature sensors on the door of the cabinet 300 If 200 is installed and nine busbars are present in the room, nine infrared temperature sensors are installed on the door.

In addition, the temperature collection indicator 400 is electrically connected to the infrared temperature sensor 200 to collect temperature data measured through the infrared temperature sensor 200 and communicate wirelessly to the temperature to the controller 500 Pass the data.

Then, the control unit 500 checks the temperature change of the corresponding bus bar 100, determines whether it is out of a predetermined temperature range, and when the predetermined reference value is exceeded, the control unit 500 warns an operator or the flow of current. Take measures to block.

The contact portion of the bolt 110 in the bus bar 100 is normally maintained without departing from the range of 35 degrees to 40 degrees, and if the bolt contact portion exceeds 80 degrees, there is a risk of fire due to overheating of the bus bar. .

Therefore, in the present invention, the alarm at the time when the temperature of the bolt coupling portion of the bus bar 100 exceeds 60 degrees, and cut off the power transmitted through the bus bar when the temperature of the bolt coupling portion of the bus bar exceeds 80 degrees. Control the risk of fire in advance.

In addition, the temperature sensor should be installed on the inside of the bus bar cabinet, but should be installed within about 50cm horizontal to the bolt fastening part of the bus bar, if the 50cm is exceeded, the temperature measurement does not proceed precisely and an error occurs. Because.

In addition, although the invention has been described in connection with the preferred embodiments mentioned, other various modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

1 is a conceptual diagram of the present invention.

Figure 2 is an installation example of the present invention.

Explanation of symbols on the main parts of the drawings

100: busbar

110: bolt

200: infrared temperature sensor

300: cabinet

400: temperature collection indicator

500: control unit

Claims (3)

Installed on the inside of the cabinet 300 and three bus bars 100 on the R, S, T phase fastened with bolts 110, Infrared temperature sensor 200 is installed in the door of the cabinet 300 and installed at a predetermined distance horizontally in a linear direction on the bolt fastening portion of the bus bar, An temperature collection indicator 400 electrically connected to the infrared temperature sensor 200 to collect temperature data measured through an infrared temperature sensor and wirelessly communicate with the infrared temperature sensor 200; Bus bar overheating prevention device using an infrared temperature sensor, characterized in that made by the temperature information from the indicator comprises a control unit 500 for alarming when the reference temperature value deviates. The method of claim 1, The control unit alarms when the temperature of the bolt coupling portion of the bus bar 100 exceeds 60 degrees, and cuts off the power transmitted through the bus bar when the temperature of the bolt coupling portion of the bus bar 100 exceeds 80 degrees. Bus bar overheating prevention device using an infrared temperature sensor, characterized in that for controlling all over. The method of claim 1, The infrared temperature sensor 200 is a bus bar overheating prevention device using an infrared temperature sensor, characterized in that installed at a distance of less than 50cm from the bus bar (100).

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